UC Davis

Like impressionist art, a multitude of subtle and complex interactions determine the behavior of biological systems but a generalized perception loses significant resolution. This is true within the discipline of soft matter, where the chemical multiplicity of the involved components and their resulting physical consequences within lamellar mesophase assemblies are commonly ignored. Therefore, it is imperative to investigate the minute thermodynamic considerations between varied lipidic lamellar mesophases and biologically relevant dopants (like surface-active agents and proteinaceous content) and their resulting physical behaviors. By using various microscopy techniques and x-ray diffraction measurements, lamellar mesophase behavior can be monitored upon the addition (in real-time or post-doping event) of these surface-active and biological substances, and the resulting analyses elucidate the microscopic information others have commonly missed. Such studies can not only enlighten scientists with a higher-level understanding of amphiphilic systems but also lead to the development of unique structural assemblies for various applications.In a larger perspective, this dissertation aims to assemble structurally-diverse lamellar mesophases and expose them to surface-active molecules (also written as surfactant or detergent) and proteinaceous content in varying methods to connect macroscopic and microscopic information. Employing various methodologies like directed aqueous hydration, water vapor hydration, and electroformation, both multilamellar and unilamellar mesophases populated by common lipids and fluorescently-tagged phospholipids were assembled. Such assemblies were then perturbed by symmetric (or internalized) or asymmetric (or external) doping of the focal substances. The consequential physical and structural properties of the mixed-component systems were then investigated to understand the impacts of chemical multiplicity. This dissertation only begins to expound the subtleties of chemistry within lamellar mesophases and question the value of generalized models of membrane behavior. Through these efforts, a new, adaptable, and inclusive intellectual framework of membranes can be developed and considered.